Terminal apparatus, base-station apparatus, communication system, and communication method

ABSTRACT

A terminal apparatus communicates with a base-station apparatus. The terminal apparatus reports partial precoder information that specifies at least one preferred candidate from among a plurality of candidates of precoders, where the partial precoder information is reported together with data from the terminal apparatus via a channel for use in data transmission. The partial precoder information is also rearranged with a same ordering for the data in a case that the partial precoder information is to be aperiodically reported. Further, the partial precoder information is rearranged with a different ordering from the ordering for the data in a case that the partial precoder information is to be periodically reported.

This application is a Continuation of U.S. application Ser. No.13/989,722, filed on May 24, 2013, which is a National Stage of PCTInternational Application No. PCT/JP2011/076686 filed on Nov. 18, 2011,which designated the United States, and on which priority is claimedunder 35 U.S.C. §120. PCT/JP2011/076686 claims priority on JapanesePatent Application No. 2010-263657, filed on Nov. 26, 2010, the entirecontents of which are hereby incorporated by reference.

TECHNICAL FIELD

The present invention relates to a terminal apparatus, a base-stationapparatus, a communication system, and a communication method.

BACKGROUND ART

A variety of mobile radio communication systems is conventionally known.Such systems include WCDMA (Wideband Code Division Multiple Access), LTE(Long Term Evolution), and LTE-A (LTE Advanced), standardized by 3GPP(Third Generation Partnership Project), and WiMAX (WorldwideInteroperability for Microwave Access) standardized by IEEE 802.16committees. In these mobile radio communication systems, a coverage areaof base-station apparatuses (a base station, a transmission station, adownlink transmitter apparatus, an uplink transmitter apparatus, eNodeB)or a transmission station functioning in practice as a base-station iscellular-structured into a plurality of cells to expand a communicationarea.

With frequencies different between adjacent cells or between adjacentsectors used, terminal apparatuses (a mobile station, a receiverstation, an uplink transmitter apparatus, a downlink receiver apparatus,a mobile terminal, and UE: User Equipment) in a cell edge area or asector edge area may perform communications in a manner free frominterference from signals transmitted from a plurality of base stations.However, in such an arrangement, a frequency usage rate is low. On theother hand, the use of the same frequency on adjacent cells or onadjacent sectors may increase the frequency usage rate. In such a case,however, a remedial step becomes necessary for a terminal apparatus inthe cell edge area against interferences.

More efficient data transmission may be achieved by adaptivelycontrolling a modulation method and an encoding ratio (MCS: Modulationand Coding Scheme), spatial multiplexing count (the number of layers,and ranks), and precoders in response to a transmission status between abase station and a terminal apparatus. Non Patent Literature 1 belowdescribes the method of controlling the modulation method and theencoding ratio.

FIG. 13 illustrates a base station 1301 and a terminal apparatus 1302 inthe LTE. When MCS, the spatial multiplexing count and the precoder areadaptively controlled on a transmitted downlink transmission signal 1303in the LTE of FIG. 13, the terminal apparatus 1302 performs thefollowing process. Specifically, the terminal apparatus 1302 calculatesreception quality information by referencing a downlink reference signal(RS: Reference Signal) included in a downlink transmission signal 1303transmitted from the base station 1301. The reception qualityinformation typically includes a rank indicator RI (Rank Indicator)specifying an appropriate spatial multiplexing count, a precoding matrixindicator PMI (Precoding Matrix Indicator) specifying a preferredprecoder, and a channel quality indicator CQI (Channel QualityIndicator) specifying an appropriate transmission rate. The terminalapparatus 1302 reports the calculated reception quality information tothe base station 1301 via an uplink channel 1304.

CITATION LIST Non Patent Literature

-   NPL 1: 3rd Generation Partnership Project; Technical Specification    Group Radio Access Network; Evolved Universal Terrestrial Radio    Access (E-UTRA); Physical layer procedures (Release 8), December    2008, 3GPP TS36. 213 V8. 8. 0 (2009-9)

SUMMARY OF INVENTION Technical Problem

In the conventional communication method, however, the process performedon the reception quality information remains fixed regardless of statuswhen the reception quality information is transmitted as control signalvia a channel for use in data transmission. The process thus serves as afactor that presents a difficulty in the increase of transmissionefficiency.

In view of the above problem, the present invention has been developed.It is an object of the present invention to provide a terminalapparatus, a base-station apparatus, a communication system, and acommunication method, according to which the reception qualityinformation is efficiently reported when the reception qualityinformation as the control information is transmitted via the channelfor use in the data transmission.

Solution to Problem

(1) The present invention has been developed to solve the above problem,and a terminal apparatus of an aspect of the present inventioncommunicates with a base-station apparatus. When reporting receptionquality information together with data to the base-station apparatus viaa channel for use in data transmission, the terminal apparatus reportsthe reception quality information using a spatial multiplexing methodidentical to a spatial multiplexing method of the data if the receptionquality information is reception quality information that is to benonoperiodically reported, and reports the reception quality informationusing a spatial multiplexing method independent of the spatialmultiplexing method of the data if the reception quality information isreception quality information that is to be periodically reported.

(2) The terminal apparatus of another aspect of the present invention isthe terminal apparatus of the aspect (1), wherein the reception qualityinformation is one piece of partial precoder information from among aplurality of pieces of partial precoder information specifying apreferred precoder.

(3) A terminal apparatus of another aspect of the present inventioncommunicates with a base-station apparatus. When reporting receptionquality information together with data to the base-station apparatus viaa channel for use in data transmission, the terminal apparatus reportspartial precoder information that specifies at least one candidate fromamong a plurality of candidates of preferred precoders if the receptionquality information is reception quality information that is to benonoperiodically reported, and reports partial precoder information thatspecifies at least one candidate from among a group of candidates withinthe plurality of candidates of the preferred precoders if the receptionquality information is reception quality information that is to beperiodically reported.

(4) A base-station apparatus of another aspect of the present inventioncommunicates with a terminal apparatus. When extracting receptionquality information reported together with data from the terminalapparatus via a channel for use in data transmission, the base-stationapparatus extracts the reception quality information based on theassumption that a spatial multiplexing method of the reception qualityinformation is identical to a spatial multiplexing method of the data ifthe reception quality information is nonoperiodically reported, andextracts the reception quality information based on the assumption thatthe spatial multiplexing method of the reception quality information isindependent of the spatial multiplexing method of the data if thereception quality information is periodically reported.

(5) The base-station apparatus of another aspect of the presentinvention is the base-station apparatus of the aspect (4), wherein thereception quality information is one piece of partial precoderinformation from among a plurality of pieces of partial precoderinformation specifying a preferred precoder.

(6) A base-station apparatus of another aspect of the present inventioncommunicates with a terminal apparatus. When extracting receptionquality information reported together with data from the terminalapparatus via a channel for use in data transmission, the base-stationapparatus extracts partial precoder information that specifies at leastone candidate from among a plurality of candidates of preferredprecoders if the reception quality information is nonoperiodicallyreported, and extracts partial precoder information that specifies atleast one candidate from among a group of candidates within theplurality of candidates of the preferred precoders if the receptionquality information is periodically reported.

(7) A communication system of another aspect of the present inventionperforms communications between a base-station apparatus and a terminalapparatus. The terminal apparatus, when reporting reception qualityinformation together with data to the base-station apparatus via achannel for use in data transmission, reports the reception qualityinformation using a spatial multiplexing method identical to a spatialmultiplexing method of the data if the reception quality information isreception quality information that is to be nonoperiodically reported,and reports the reception quality information using a spatialmultiplexing method independent of the spatial multiplexing method ofthe data if the reception quality information is reception qualityinformation that is to be periodically reported. The base-stationapparatus, when extracting the reception quality information reportedtogether with the data from the terminal apparatus, extracts thereception quality information based on the assumption that the spatialmultiplexing method of the reception quality information is identical tothe spatial multiplexing method of the data if the reception qualityinformation is nonoperiodically reported, and extracts the receptionquality information based on the assumption that the spatialmultiplexing method of the reception quality information is independentof the spatial multiplexing method of the data if the reception qualityinformation is periodically reported.

(8) A communication system of another aspect of the present inventionperforms communications between a base-station apparatus and a terminalapparatus. The terminal apparatus, when reporting reception qualityinformation together with data to the base-station apparatus via achannel for use in data transmission, reports partial precoderinformation that specifies at least one candidate from among a pluralityof candidates of preferred precoders if the reception qualityinformation is reception quality information that is to benonoperiodically reported, and reports partial precoder information thatspecifies at least one candidate from among a group of candidates withinthe plurality of candidates of preferred precoders if the receptionquality information is reception quality information that is to beperiodically reported. The base-station apparatus, when extracting thereception quality information reported together with the data from theterminal apparatus, extracts partial precoder information that specifiesat least one candidate from among a plurality of candidates of preferredprecoders if the reception quality information is nonoperiodicallyreported, and extracts partial precoder information that specifies atleast one candidate from among a group of candidates within theplurality of candidates of preferred precoders if the reception qualityinformation is periodically reported.

(9) A communication method of a terminal apparatus of another aspect ofthe present invention is a communication method for communication with abase-station apparatus, and includes, when reception quality informationis transmitted together with data via a channel for use in datatransmission, a step of reporting the reception quality informationusing a spatial multiplexing method identical to a spatial multiplexingmethod of the data if the reception quality information is receptionquality information that is to be nonoperiodically reported, and a stepof reporting the reception quality information using a spatialmultiplexing method independent of the spatial multiplexing method ofthe data if the reception quality information is reception qualityinformation that is to be periodically reported.

(10) A communication method of a terminal apparatus of another aspect ofthe present is a communication method for communication with abase-station apparatus, and includes, when reception quality informationis transmitted together with data via a channel for use in datatransmission, a step of reporting partial precoder information thatspecifies at least one candidate from among a plurality of candidates ofpreferred precoders if the reception quality information is receptionquality information that is to be nonoperiodically reported, and a stepof reporting partial precoder information that specifies at least onecandidate from among a group of candidates within the plurality ofcandidates of the preferred precoders if the reception qualityinformation is reception quality information that is to be periodicallyreported.

(11) A communication method of a base-station apparatus of anotherembodiment of the present invention is a communication method forcommunication with a terminal apparatus, and includes, when receptionquality information reported together with data from the terminalapparatus via a channel for use in data transmission is extracted, astep of extracting the reception quality information based on theassumption that a spatial multiplexing method of the reception qualityinformation is identical to a spatial multiplexing method of the data ifthe reception quality information is nonoperiodically reported, and astep of extracting the reception quality information based on theassumption that the spatial multiplexing method of the reception qualityinformation is independent of the spatial multiplexing method of thedata if the reception quality information is periodically reported.

(12) A communication method of a base-station apparatus of anotheraspect of the present invention is a communication method forcommunication with a terminal apparatus, and includes, when receptionquality information reported together with data from the terminalapparatus via a channel for use in data transmission is extracted, astep of extracting partial precoder information that specifies at leastone candidate from among a plurality of candidates of preferredprecoders if the reception quality information is nonoperiodicallyreported, and a step of extracting partial precoder information thatspecifies at least one candidate from among a group of candidates withinthe plurality of candidates of the preferred precoders if the receptionquality information is periodically reported.

Advantageous Effects of Invention

According to the present invention, reception quality information isefficiently reported when the reception quality information as controlinformation is transmitted via a channel for use in data transmission.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 diagrammatically illustrates a configuration of a communicationsystem of an embodiment of the present invention.

FIG. 2 illustrates an example of a downlink radio frame structure of thepresent embodiment.

FIG. 3 illustrates an example of an uplink radio frame structure of thepresent embodiment.

FIG. 4 illustrates an example of a block structure of a base-stationapparatus of the present embodiment.

FIG. 5 illustrates an example of a block structure of a terminalapparatus of the present embodiment.

FIG. 6 illustrates an example of a procedure in a nonperiodic feedbackmode of the present embodiment.

FIG. 7 illustrates a mapping example in the nonperiodic feedback mode ofthe present embodiment.

FIG. 8 illustrates an example of the procedure in a periodic feedbackmode of the present embodiment.

FIG. 9 illustrates another example of the procedure in the periodicfeedback mode of the present embodiment.

FIG. 10 illustrates another example of the procedure in the periodicfeedback mode on the present embodiment.

FIG. 11 illustrates an example of the procedure in an uplink datatransmission in the present embodiment.

FIG. 12 illustrates a mapping example in a piggyback operation in theperiodic feedback mode of the present embodiment.

FIG. 13 diagrammatically illustrates a configuration of a communicationsystem.

DESCRIPTION OF EMBODIMENTS

Embodiments of the present invention are described below with referenceto the drawings. In the following discussion, like elements aredesignated with like reference symbols, and are identified with the samenames and have the same functions. The detailed description thereof,once described, is not repeated.

FIG. 1 diagrammatically illustrates a configuration of a communicationsystem of an embodiment of the present invention. The communicationsystem of FIG. 1 is based on an LTE-A system. The communication systemincludes a base-station apparatus (a base station, a transmitterstation, a downlink transmitter station, an uplink receiver station,eNodeB) 101 forming cells, and a terminal apparatus (a mobile station, areceiver station, an uplink transmitter station, a downlink receiverstation, a mobile terminal, UE: User Equipment) 102.

When transmission parameters including MCS (Modulation and CodingScheme), rank, and precoder are adaptively controlled on a downlinktransmission signal 103 transmitted in Cell #0 and Cell #1, the terminalapparatus 102 performs a process described below. More specifically, theterminal apparatus 102 calculates reception quality information byreferencing a downlink reference signal (RS: Reference Signal) includedin a downlink transmission signal 103 transmitted from the base-stationapparatus 101. For example, the reception quality information includes arank indicator RI (Rank Indicator) specifying a preferred spatialmultiplexing count, a plurality of pieces partial precoder informationPI (Precoder Information) specifying preferred precoders (PreferredPrecoder), and a channel quality indicator CQI (Channel QualityIndicator) specifying a preferred transmission rate (a modulationmethod, an encoding ratio, and a length of transport block). Next, theterminal apparatus 102 reports the calculated reception qualityinformation to the base-station apparatus 101 via an uplink channel 104.

In the discussion that follows, the terminal apparatus 102 reports tothe base-station apparatus 101 partial precoder information 1 (PI1 asfirst partial precoder information) and precoder information 2 (PI2 assecond partial precoder information), as partial precoder informationPI. For example, the terminal apparatus 102 specifies a preferredprecoder W(i,j) using an index i represented by m bits as PI1, and anindex j represented by n bits as PI2. Alternatively, the terminalapparatus 102 specifies a preferred precoder W^((r))(i,j) using a rankr.

Here, W(i,j) is a matrix that is uniquely determined by i and j. Adetermination method of the matrix (codebook) is shared by thebase-station apparatus 101 and the terminal apparatus 102. In otherword, the codebook is a plurality of candidates of preferred precoders.A method of calculating a precoder that increases downlink receptionsignal power in view of a downlink transmission path may be used as acalculation method of a preferred precoder.

FIG. 2 illustrates an example of a downlink radio frame structure of thepresent embodiment. Referring to FIG. 2, an OFDM (Orthogonal FrequencyDivision Multiplex) scheme is used in downlink. Assigned to the downlinkare a physical downlink control channel (PDCCH), and a physical downlinkshared channel (PDSCH). A downlink reference signal (RS) is multiplexedon a portion of PDSCH.

The downlink radio frame includes a downlink resource block (RB) pair.The downlink RB pair is a unit according to which the downlink radioresource is assigned. The downlink RB pair includes a predeterminedfrequency bandwidth (RB bandwidth) and a time band (two slots=onesubframe).

One downlink RB pair includes two downlink RBs (RB bandwidth×slot) thatare two consecutively linked in the time domain. One downlink RBincludes 12 subcarriers in the frequency domain, and includes 7 OFDMsymbols in the time domain.

A physical downlink control channel is a physical channel through whichdownlink control information is transmitted. The downlink controlinformation may include a terminal apparatus identifier, schedulinginformation of a downlink shared channel, scheduling information of anuplink shared channel, a modulation method, an encoding ratio, and aretransmission parameter

A downlink subframe in a single component carrier (CC) is illustrated.The downlink subframe may be defined on a per CC basis, and the downlinksubframe is almost in synchronization with the CC.

FIG. 3 illustrates an example of an uplink radio frame structure of thepresent embodiment. Referring to FIG. 3, an SC-FDMA (SingleCarrier-Frequency Division Multiple Access) scheme is used in uplink.Assigned to the uplink are a physical uplink shared channel (PUSCH), anda physical uplink control channel (PUCCH). An uplink reference signal(RS) is assigned on a portion of PUSCH or PUCCH.

The uplink radio frame includes an uplink RB pair. The uplink RB pair isa unit according to which the uplink radio resource is assigned. Theuplink RB pair includes a predetermined frequency bandwidth (RBbandwidth) and a time band (two slots=one subframe).

One uplink RB pair includes two uplink RBs (RB bandwidth×slot) that aretwo consecutively linked in the time domain. One uplink RB includes 12subcarriers in the frequency domain, and includes 7 SC-FDMA symbols inthe time domain.

FIG. 4 is a block diagram diagrammatically illustrating the base-stationapparatus 101 of the present embodiment. Referring to FIG. 4, thebase-station apparatus 101 includes a downlink subframe generator module401, OFDM signal transmitter units 404, a transmitter antenna(base-station transmitter antenna) 405, receiver antennas (base-stationtransmitter antennas) 406, SC-FDMA signal receiver units 407, a filterunit 408, a code word processor unit 412, and an upper layer 413. Thedownlink subframe generator module 401 includes a physical downlinkcontrol channel generator unit 402, and a downlink reference signalgenerator unit 403. The filter unit 408 includes a feedback informationextractor unit 409.

FIG. 5 illustrates an example of a block structure of the terminalapparatus 102 of the present embodiment. Referring to FIG. 5, theterminal apparatus 102 includes receiver antennas (terminal receiverantennas) 501, OFDM signal receiver units 502, a downlink subframeprocessor module 503, an upper layer 506, a feedback informationgenerator unit 507, code word generator units 508, an uplink subframegenerator unit 509, an SC-FDMA signal transmitter unit 511, andtransmitter antennas (terminal transmitter antennas) 512. The downlinksubframe processor module 503 includes a downlink reference signalextractor unit 504 and a physical downlink control channel extractorunit 505. The uplink subframe generator unit 509 includes an uplinkreference signal generator unit 510.

Referring to FIGS. 4 and 5, a downlink flow of transmission andreception is described below. In the base-station apparatus 101, thedownlink subframe generator module 401 performs a modulation process ontransmission data (also referred to as a transport block) of each codeword (a transmission data string in a physical layer) transmitted fromthe upper layer 411. The modulation process includes an error correctionencoding operation, a rate matching operation, a PSK (Phase ShiftKeying) modulation operation, and a QAM (Quadrature AmplitudeModulation) operation. The downlink subframe generator module 401 thusconverts the transmission data into a modulation symbol string. Thedownlink subframe generator module 401 maps the modulation symbol stringto a resource element (RE) that serves as a mapping unit of themodulation symbol string. The downlink subframe generator module 401performs a precoding operation on the mapped modulation symbol stringusing a precoder specified by the upper layer 411. The RE in thedownlink is defined in response to each subcarrier on the OFDM symbol.The transmission data string transmitted from the upper layer 411includes control data for RRC (Radio Resource Control) signaling.

The physical downlink control channel generator unit 402 generates aphysical downlink control channel in response to an instruction from theupper layer 411. Control information in the physical downlink controlchannel includes a transmission parameter in the downlink, a resourceassignment in the uplink, a transmission parameter in the uplink, andCQI request. The downlink reference signal generator unit 403 generatesa downlink reference signal DLRS (Down Link Reference Signal).

The downlink subframe generator module 401 maps the physical downlinkcontrol channel and DLRS to the RE in the downlink subframe. The OFDMsignal transmitter unit 404 modulates a downlink subframe generated bythe downlink subframe generator module 401. The OFDM signal transmitterunit 404 transmits via the transmitter antenna 405 an OFDM signalobtained through modulation.

In the terminal apparatus 102, the OFDM signal receiver unit 502receives an OFDM signal via the receiver antenna 501. The OFDM signalreceiver unit 502 performs an OFDM demodulation operation on thereceived OFDM signal. The downlink subframe processor module 503extracts received data from the received downlink subframe, and thensends the extracted received data to the upper layer 506. Morespecifically, the downlink subframe processor module 503 extracts thereceived data from the downlink subframe by performing on the downlinksubframe a demodulation operation and an error correction decodingoperation as opposed to the modulation operation, the rate matchingoperation, and the error correction encoding operation performed by thedownlink subframe generator module 401.

The downlink reference signal extractor unit 504 extracts DLRS generatedby the downlink reference signal generator unit 403 and mapped by thedownlink subframe generator module 401, and then sends the extractedDLRS to the feedback information generator unit 507. The physicaldownlink control channel extractor unit 505 extracts the controlinformation included in the physical downlink control channel generatedby the physical downlink control channel generator unit 402 and mappedby the downlink subframe generator module 401, and then sends theextracted control information to the upper layer 506.

The operations of the OFDM signal transmitter unit 404 and thetransmitter antenna 405 in the base-station apparatus 101 and theoperations of the receiver antenna 501, the OFDM signal receiver unit502, and the downlink subframe processor module 503 in the terminalapparatus 102 are performed on each cell (CC) of the downlink. Thefeedback information generator unit 507 generates the reception qualityinformation (feedback information) of a plurality of downlink cells.

With reference to FIGS. 4 and 5, the uplink flow of transmission andreception is described. In the terminal apparatus 102, the code wordgenerator unit 508 converts the transmission data into a code word CW(Code Word) by performing operations including the error correctionencoding operation, and the rate matching operation on the transmissiondata (also referred to as a transport block) on each code wordtransmitted from the upper layer 506.

In response to an instruction from the upper layer 506, the feedbackinformation generator unit 507 generates feedback information byencoding RI, PI1, PI2, CQI and the like using the DLRS extracted by thefeedback information generator unit 507. The uplink reference signalgenerator unit 510 generates an uplink reference signal ULRS (UplinkReference Signal).

The uplink subframe generator unit 509 rearranges the code wordmodulation symbol string and the feedback information in accordance witha predetermined method. The uplink subframe generator unit 509 then mapsthe rearranged code word modulation symbol string and feedbackinformation together with the uplink reference signal in the uplinksubframe. The SC-FDMA signal transmitter unit 511 generates an SC-FDMAsignal by performing an SC-FDMA modulation operation on the uplinksubframe. The SC-FDMA signal transmitter unit 511 transmits thegenerated SC-FDMA signal via the transmitter antenna 512.

In the base-station apparatus 101, the SC-FDMA signal receiver unit 407receives the SC-FDMA signal via the receiver antenna 406. The SC-FDMAsignal receiver unit 407 performs an SC-FDMA demodulation operation onthe received SC-FDMA signal. The downlink subframe processor module 503extracts a code word from the received uplink subframe, and sends theextracted code word to the code word processor unit 410. The code wordprocessor unit 410 extracts received data from the code word, and sendsthe extracted received data to the upper layer 411. More specifically,the code word processor unit 410 extracts the received data from thecode word by performing on the code word a rate matching operation andan error correction decoding operation as opposed to the rate matchingoperation and the error correction encoding operation performed by thecode word generator unit 508.

In response to an instruction from the upper layer 411, the feedbackinformation extractor unit 409 in the filter unit 408 extracts thefeedback information generated by the feedback information generatorunit 507 and mapped by the downlink subframe generator module 401. Thefeedback information extractor unit 409 decodes the extracted feedbackinformation and then sends the decoded feedback information to the upperlayer 411. The filter unit 408 through a filtering operation thereofdetects a signal on each code word by performing on each signal receivedvia the receiver antenna 406 a ZF (Zero Forcing) operation, an MMSE(Minimum Mean Square Error) operation, and an MLD (Maximum LikelihoodDetection) operation.

FIG. 6 illustrates an example of a procedure of the present embodiment.The procedure of FIG. 6 is a procedure in a nonperiodic feedback mode(the first feedback mode) in which RI, PI1, PI2, and W-CQI arenonperiodically fed back. First, the base-station apparatus 101 sets afeedback parameter in the terminal apparatus 102 via RRC signaling (stepS601). The base-station apparatus 101 then notifies the terminalapparatus 102 of a CQI request that is information instructing anonperiodic feedback (step S602). The base-station apparatus 101 assignsa resource (a physical uplink shared channel) that is for notifying ofthe feedback information at the same time.

The terminal apparatus 102 that is instructed to perform the nonperiodicfeedback reports RI, PI1, PI2, and W-CQI to the base-station apparatus101 at the same time (at the same timing) in accordance with the setfeedback parameter (step S603). In the nonperiodic feedback mode forfeeding back S-CQI, the terminal apparatus 102 further reports S-CQI tothe base-station apparatus 101 at the same time. The terminal apparatus102 here reports S-CQI of a plurality of bandwidths BP to thebase-station apparatus 101 at the same time.

In the discussion here, the notification of the CQI request to theterminal apparatus 102 in step S602 is performed using dynamic signalingvia the physical downlink control channel. The present invention is notlimited to this method. For example, a similar advantage may be providedif the base-station apparatus 101 instructs the terminal apparatus 102to perform the nonperiodic feedback using quasi-static signaling via theRRC signaling. In such a case, a subframe to be further reported ispreferably specified.

Mapping of the feedback information in the nonperiodic feedback mode isdescribed next. FIG. 7 illustrates a mapping example of the feedbackinformation. The rearrangement and mapping in FIG. 7 are applicable tothe case in which a plurality of CWs (CW0 and CW1) over the uplink aretransmitted. It is noted that CW0 and CW1 are transmitted using layer 1and layer 2, respectively. The term “layer” refers to an index ofspatial multiplexing. A term “layer count” refers to the spatialmultiplexing count. The ULRS is mapped to fourth and eleventh SC-FDMAsymbols at the layers. The feedback information including RI and theother feedback information (such as W-CQI, PI1, and PI2) are rearrangedas illustrated in FIG. 7. The parameters herein are discussed forexemplary purposes only, and other parameters may be also be used. Forexample, if only CW0 is transmitted, the terminal apparatus 102 simplyperforms a mapping operation like the mapping operation at the layer 1of FIG. 7.

More specifically, CQI, PI1, and PI2 are concatenated with CW0, first.In this case, the feedback information including CQI and PI2, and thenCW0 are concatenated in that order. Concatenated symbol strings arerearranged beginning with the front ends of the strings, for example, inthe order of a front end portion of a first SC-FDMA symbol at the layer1, a front end portion of a second SC-FDMA symbol at the layer 1, . . ., a front end portion of a fourteenth SC-FDMA symbol at the layer 1, asecond portion of the first SC-FDMA symbol at the layer 1 . . . andthus, the SC-FDMA symbols of the layer for transmission of CW0 arearranged for sequential mapping beginning with the front ends of theSC-FDMA. On the other hand, CW1 is rearranged beginning with the frontends of the strings in the order of a front end portion of a firstSC-FDMA symbol at the layer 2, a front end portion of a second SC-FDMAsymbol at the layer 2, . . . , a front end portion of a fourteenthSC-FDMA symbol at the layer 2, a second portion of the first SC-FDMAsymbol at the layer 2 . . . and thus, the SC-FDMA symbols of the layerfor transmission of CW1 are arranged for sequential mapping beginningwith the front ends of the SC-FDMA. RI is rearranged so that RI ismapped to part or all of the SC-FDMA symbols adjacent to ULRS at all thelayers (as illustrated in FIG. 7, for example, to a rear portion of eachof second, sixth, ninth, and thirteenth SC-FDMA symbols at the layer 1and the layer 2). More specifically, the terminal apparatus 102transmits (reports) to the base-station apparatus 101 RI, CQI, PI1, andPI2 using different spatial multiplexing counts, or independent spatialmultiplexing methods and mapping methods.

The uplink subframe generator unit 509 performs the rearrangementoperation and the mapping operation in response to an instruction fromthe upper layer 506. On the other hand, the feedback informationextractor unit 409 in the base-station apparatus 101 acquires thefeedback information in response to an instruction from the upper layer411 by performing a demapping operation as opposed to the mappingoperation of the uplink subframe generator unit 509 and a rearrangementoperation to restore an original rearrangement to reverse therearrangement operation performed by the uplink subframe generator unit509.

A codebook used in the calculation of PI1 and PI2 is described here. Aspreviously described, the terminal apparatus 102 specifies the preferredprecoder W(i,j) using an index i represented by m bits as PI1, and anindex j represented by n bits as PI2. The codebook defines a maximum of2^(m+n) types of W(i,j). In the nonperiodic feedback mode, the degree offreedom of feedback is increased by increasing the degree of freedom inthe selection of W(i,j) in the codebook.

FIG. 8 illustrates a procedure in a periodic feedback mode of thepresent embodiment. The procedure of FIG. 8 is an example of theprocedure of a periodic feedback mode (a second feedback mode) in whichRI, PI1, PI2, and W-CQI (Wideband CQI) in a cell are periodically fedback. It is noted that W-CQI is one type of CQI that represents a systembandwidth (component carrier bandwidth). The term feedback mode refersto settings including a combination of content of the reception qualityinformation fed back from the terminal apparatus 102 to the base-stationapparatus 101, a measurement method or a generation method of thecontent, a feedback method of the content, and a resource used infeedback.

The base-station apparatus 101 sets a parameter of the feedback in theterminal apparatus 102 via RRC signaling, and instructs the terminalapparatus 102 to perform a second feedback operation mode (step S801).The terminal apparatus 102 which has been instructed to perform theperiodic feedback periodically reports PI, PI1 (step S802), PI2 andW-CQI (step S803) to the base-station apparatus 101 via a physicaluplink control channel in accordance with the set feedback parameter. Inthe following discussion, the report in step S802 is referred to as a“feedback type 1A,” and the report in step S803 is referred to as a“feedback type 1B.”

FIG. 9 illustrates another example of the procedure in the periodicfeedback mode of the present embodiment. The procedure of FIG. 9 is anexample of the procedure of a periodic feedback mode (a third feedbackmode) in which RI, PTI (Precoder Type Indication), PI1, PI2, W-CQI, andS-CQI (Subband-CQI) in a cell are periodically fed back. In the feedbackmode in which S-CQI (Subband-CQI) is periodically fed back, the terminalapparatus 102 further reports S-CQI periodically. Here, S-CQI representsa bandwidth (Bandwidth Part) of a plurality of narrow bandwidths intowhich the system bandwidth (the component carrier bandwidth) issegmented. More specifically, BP includes one or more subbands (BP issegmented into the subbands), and S-CQI is the CQI of one of thesubbands contained in BP. As will be described below, PTI is an indexaccording to which the content to be fed back is switched.

First, the base-station apparatus 101 sets a feedback parameter in theterminal apparatus 102 via RRC signaling, and instructs the terminalapparatus 102 to perform the third instruction mode (step S901). Theterminal apparatus 102 that has been instructed to perform the periodicfeedback periodically reports RI and PTI (step S902) to the base-stationapparatus 101 via the physical uplink control channel in accordance withthe set feedback parameter.

If PTI reported in step S902 indicates a precoder that reports PI2 ofeach subband, the terminal apparatus 102 reports PI1 and W-CQI (stepS903) and PI2 and S-CQI (step S903) periodically to the base-stationapparatus 101 via the physical uplink control channel in accordance withthe set feedback parameter. PI2 herein is the PI2 calculated on thesubband corresponding to S-CQI concurrently transmitted.

On the other hand, if PTI reported in step 902 indicates a precoder thatreports PI2 in the system bandwidth (component carrier bandwidth), theterminal apparatus 102 reports PI2 and W-CQI (step S905) and S-CQI (stepS906) periodically to the base-station apparatus 101 via the physicaluplink control channel in accordance with the set feedback parameter. Insuch a case, the terminal apparatus 102 uses a codebook that specifies apreferred precoder by reporting only PI2 instead of PI1. In thefollowing discussion, the report in step S902 is referred to as a“feedback type 2A,” the report in step S903 is referred to as a“feedback type 2B,” the report in step S904 is referred to as a“feedback type 2C,” the report in step S905 is referred to as a“feedback type 2D,” and the report in step S906 is referred to as a“feedback type 2E.” The feedback type 2D may include the reportidentical to that of the feedback type 1B, or the feedback type 2D mayallow the calculation methods of PI2 and W-CQI to be individually set.

FIG. 10 illustrates another example of the procedure in the periodicfeedback mode of the present embodiment. The procedure of FIG. 10 is anexample of the procedure of a periodic feedback mode (a fourth feedbackmode) in which RI, PI1, PI2, W-CQI, and S-CQI in a cell are periodicallyfed back. The base-station apparatus 101 sets a feedback parameter inthe terminal apparatus 102 via RRC signaling, and instructs the terminalapparatus 102 to perform the fourth feedback mode (step S1001). Theterminal apparatus 102 which has been instructed to perform the periodicfeedback reports RI (step S1002) periodically to the base-stationapparatus 101 in accordance with the set feedback parameter.

The terminal apparatus 102 next reports PI1, PI2, and W-CQI (step S1003)and S-CQI (step S1003) periodically to the base-station apparatus 101via the physical uplink control channel in accordance with the setfeedback parameter. Here, the report in step S1002 is referred to as a“feedback type 3A,” the report in step S1003 is referred to as a“feedback type 3B,” and the report in step S1004 is referred to as a“feedback type 3C.” The feedback type 3C may include the reportidentical to that of the feedback type 2E, or the feedback type 3C mayallow the calculation methods of S-CQI to be individually set.

FIG. 11 illustrates an example of the procedure of the uplink (UL) datatransmission of the present embodiment. Referring to FIG. 11, thebase-station apparatus 101 notifies the terminal apparatus 102 of a ULgrant as the control information (step S1101). The control informationincludes allocation information that indicates an allocation of thephysical uplink shared channel serving as a channel for uplink datatransmission in the physical layer. The terminal apparatus 102 havingbeen notified of the UL grant transmits UL data to the base-stationapparatus 101 using the physical uplink shared channel indicated by theallocation information (step S1102).

In the periodic feedback mode, any of the feedback information reports(step S802, step S803, step S902, step S903, step S904, step S905, stepS906, step S1002, step S1003, and step S1004) is typically performed viathe physical uplink control channel as a channel for reporting thecontrol information at the physical layer. However, if in step S1101,the physical uplink shared channel as a channel for transmitting data atthe physical layer is allocated at the timing when any of the feedbackinformation reports is performed, the terminal apparatus 102 reports theUL data together with the feedback information to the base-stationapparatus 101 via the physical uplink shared channel. An operation ofreporting the control information at the physical layer via the physicaluplink shared channel instead of the physical uplink control channel isreferred to as a “piggyback” operation.

The mapping of the feedback information during the piggyback operationin the periodic feedback mode is described. FIG. 12 illustrates amapping example of the feedback information. The rearrangement andmapping illustrated in FIG. 12 apply when a plurality of CWs (CW0 andCW1) are transmitted over the uplink. The following discussion is basedon the assumption that CW0 and CW1 are transmitted using the layer 1 andthe layer 2, respectively. The mapping discussed herein refers to themapping of the feedback type 1A during the piggyback operation.

More specifically, the terminal apparatus 102 rearranges the feedbackinformation including RI and PI1 so that the feedback information ismapped to part or all of the SC-FDMA symbols adjacent to ULRS at all thelayers (as illustrated in FIG. 12, for example, to a rear portion ofeach of second, sixth, ninth, and thirteenth SC-FDMA symbols at thelayer 1 and the layer 2). More specifically, the terminal apparatus 102reliably transmits (reports) to the base-station apparatus 101 RI, andPI1 using a spatial multiplexing method independent of the UL data (inpractice, using a method of reducing the spatial multiplexing count).

The uplink subframe generator unit 509 performs the rearrangementoperation and the mapping operation in response to an instruction fromthe upper layer 506. On the other hand, the feedback informationextractor unit 409 in the base-station apparatus 101 acquires thefeedback information in response to an instruction from the upper layer411 by performing a demapping operation as opposed to the mappingoperation of the uplink subframe generator unit 509 and a rearrangementoperation to restore an original rearrangement to reverse therearrangement operation performed by the uplink subframe generator unit509.

A codebook used in the calculation of PI1 and PI2 during the piggybackoperation in the periodic feedback mode is described here. The codebookused herein is the same codebook as the one used in the nonperiodicfeedback mode. In the periodic feedback mode, however, an overheadinvolved in the feedback information may be reduced by lowering thedegree of freedom of the selection of W(i,j) in the codebook.

More specifically, the terminal apparatus 102 partially extracts(subsamples) a value taken by an index i represented by m bits as PI1from 0, 1, . . . , 2^(m)−1, thereby setting the bit count needed by PI1to be smaller than m bits. Similarly, the terminal apparatus 102 setsthe bit count for PI2 to be smaller than n bits. The bit counts of PI1and PI2 are thus reduced by restraining the number of types W(i,j)expressed by PI1 and PI2.

As described above, the terminal apparatus 102 multiplexes PI1 into asingle CW when PI1 is reported to the base-station apparatus 101 via thephysical uplink control channel in the nonperiodic feedback mode. On theother hand, the terminal apparatus 102 multiplexes PI1 into all the CWswhen PI1 is reported to the base-station apparatus 101 via the physicaluplink shared channel in the periodic feedback mode during the piggybackoperation. In other words, the terminal apparatus 102 transmits PI1 byspatial-multiplexing PI1 in the same manner as the UL data when PI1 isreported to the base-station apparatus 101 via the physical uplinkcontrol channel in the nonperiodic feedback mode. On the other hand, theterminal apparatus 102 transmits PI1 via a spatial multiplexing methodindependent of a spatial multiplexing method of the UL data (inpractice, with the spatial multiplexing count being 1) when PI1 isreported to the base-station apparatus 101 via the physical uplinkshared channel in the periodic feedback mode during the piggybackoperation.

When the terminal apparatus 102 reports the reception qualityinformation to the base-station apparatus 101 via the physical uplinkshared channel, the terminal apparatus 102 thus transmits the receptionquality information in a reliable method if there is a possibility thatthe reception quality information may be a cause for erratictransmission. If the reception quality information may not be a causefor erratic transmission, the terminal apparatus 102 transmits thereception quality information using the method with the involvedoverhead reduced. For this reason, the terminal apparatus 102 canefficiently feed back the reception quality information.

When PI1 or PI2 is reported to the base-station apparatus 101 via thephysical uplink shared channel in the nonperiodic feedback mode, theterminal apparatus 102 does not subsample the codebook of PI1 or PI2. Onthe other hand, when PI1 or PI2 is reported to the base-stationapparatus 101 via the physical uplink shared channel in the periodicfeedback mode during the piggyback operation, the terminal apparatus 102subsamples the codebook of PI1 or PI2. In other words, the terminalapparatus 102 selects a preferred precoder from a group of candidatesfrom among the plurality of preferred precoders. More specifically, whenPI1 or PI2 is reported to the base-station apparatus 101 via thephysical uplink shared channel in the nonperiodic feedback mode, theterminal apparatus 102 transmits PI1 or PI2 expressable by X bits to thebase-station apparatus 101. On the other hand, when PI1 or PI2 isreported to the base-station apparatus 101 via the physical uplinkshared channel in the periodic feedback mode during the piggybackoperation, the terminal apparatus 102 transmits PI1 or PI2 expressableby Y bits (Y<X) to the base-station apparatus 101.

In this way, when the reception quality information is reported to thebase-station apparatus 101 via the physical uplink shared channel, theterminal apparatus 102 transmits detailed reception quality informationif a CQI request is received, and transmits the reception qualityinformation through the method with the overhead reduced if no CQIrequest is received. For this reason, the terminal apparatus 102 mayefficiently perform the feedback of the reception quality information.

In the above discussion, the terminal apparatus 102 reports PI1 to thebase-station apparatus 101 in each feedback mode. The present inventionis not limited to this method. For example, if the number of transmitterantennas of the base-station apparatus 101 is small, PI1 may not bereported. In such a case, the codebook may be arranged so that apreferred precoder is uniquely determined by PI2 only. The feedback typeincluding PI1 may be a feedback type that reports content other thanPI1.

A program implementing part or all of the functions of the base-stationapparatus 101, and a program implementing part or all of the functionsof the terminal apparatus 102 may be recorded onto a computer readablerecording medium. The programs recorded on the computer readablerecording medium may be read onto a computer system. The processes ofeach element of the base-station apparatus 101 and the terminalapparatus 102 may thus be executed by running the programs on thecomputer system. The term “computer system” refers to an OS (OperatingSystem) and hardware such as peripheral devices.

The term “computer system” includes a homepage providing environment (ordisplay environment) if a WWW system is used.

The term “computer readable recording medium” refers to a portablemedium, such as a flexible disk, a magneto-optical disk, ROM, or CD-ROM,or a recording device, such as a hard disk, built into the computersystem. The term “computer readable recording medium” may include acommunication line that holds dynamically temporarily the program. Thecommunication line transmits the program via a communication channelsuch as a network like the Internet or a telephone line. The “computerreadable recording medium” may also include a volatile memory in thecomputer system that may be a server or a client and stores the programfor a predetermined period of time. The program may implement part ofthe above-described function. The part of the above-described functionmay be used in combination with a program previously recorded on thecomputer system.

The processes of the elements may be implemented by integrating part orall of the functions of the base-station apparatus 101 into anintegrated circuit, and part or all of the functions of the terminalapparatus 102 into an integrated circuit. The function blocks of thebase-station apparatus 101 and the terminal apparatus 102 may beindividually implemented using microchips, and part or all of thefunction blocks may be integrated into a microchip. The technique ofintegration is not limited to LSI. A dedicated circuit or ageneral-purpose processor may be employed. If a technique of circuitintegration replacing the LSI appears with the advance of semiconductortechnique, an integrated circuit resulting from the technique may alsobe used.

The embodiment of the present invention has been described in detailwith reference to the drawings. The specific structure of the embodimentis not limited to the structure described above. A variety of designchanges is possible without departing from the scope of the presentinvention. A variety of modification is possible without departing fromthe scope of the prevent invention. An embodiment resulting fromcombining technical means disclosed in the different embodiments mayalso fall within the scope of the present invention. The embodimentsinclude elements that may have similar functions, and if an embodimentis constructed by interchanging the elements having the similarfunctions, such an embodiment may also falls within the scope of thepresent invention.

INDUSTRIAL APPLICABILITY

The present invention is preferable for use in a radio terminalapparatus, a radio base-station apparatus, a radio communication system,and a radio communication method.

REFERENCE SIGNS LIST

101 and 1301 Base-station apparatuses, 102 and 1302 Terminalapparatuses, 103, 1303 Downlink transmission signals, 104 and 1304Feedback information, 401 Downlink subframe generator module, 402Physical downlink control channel generator unit, 403 Downlink referencesignal generator unit, 404 OFDM signal transmitter unit, 405 Transmitterantenna, 406 Receiver antenna, 407 SC-FDMA signal receiver unit, 408Filter unit, 409 Feedback information extractor unit, 410 Code wordprocessor unit, 411 Upper layer, 501 Receiver antenna, 502 OFDM signalreceiver unit, 503 Downlink subframe processor module, 504 Downlinkreference signal extractor unit, 505 Physical downlink control channelextractor unit, 506 Upper layer, 507 Feedback information generatorunit, 508 Code word generator unit, 509 Uplink subframe generator unit,510 Uplink reference signal generator unit, 511 SC-FDMA signaltransmitter unit, 512 Transmitter antenna

The invention claimed is:
 1. A terminal apparatus configured tocommunicate with a base-station apparatus, the terminal apparatuscomprising: receiving circuitry configured to receive controlinformation used for a scheduling of a Physical Uplink Shared Channel(PUSCH); and transmitting circuitry configured to report partialprecoder information that specifies at least one preferred candidatefrom among a plurality of candidates of precoders, the partial precoderinformation being reported together with data from the terminalapparatus on the PUSCH, wherein in a case that the partial precoderinformation is to be aperiodically reported, modulation symbols of thepartial precoder information and modulation symbols of the data areinterleaved jointly, and in a case that the partial precoder informationis to be periodically reported, modulation symbols of the partialprecoder information and modulation symbols of the data are interleavedseparately.
 2. A base-station apparatus configured to communicate with aterminal apparatus, the base-station apparatus comprising: transmittingcircuitry configured to transmit control information used for ascheduling of a Physical Uplink Shared Channel (PUSCH); and receivingcircuitry configured to receive partial precoder information thatspecifies at least one preferred candidate from among a plurality ofcandidates of precoders, the partial precoder information being reportedtogether with data from the terminal apparatus on the PUSCH, whereinmodulation symbols of the partial precoder information and modulationsymbols of the data are interleaved jointly in a case that the partialprecoder information is aperiodically reported, and modulation symbolsof the partial precoder information and modulation symbols of the dataare interleaved separately in a case that the partial precoderinformation is periodically reported.
 3. A communication method of aterminal apparatus configured to communicate with a base-stationapparatus, the communication method comprising: receiving controlinformation used for a scheduling of a physical Uplink Shared Channel(PUSCH); and reporting partial precoder information that specifies atleast one preferred candidate from among a plurality of candidates ofprecoders, the partial precoder information being reported together withdata from the terminal apparatus on the PUSCH, wherein in a case thatthe partial precoder information is to be aperiodically reported,modulation symbols of the partial precoder information and modulationsymbols of the data are interleaved jointly; and in a case that thepartial precoder information is to be periodically reported, modulationsymbols of the partial precoder information and modulation symbols ofthe data are interleaved separately.
 4. A communication method of abase-station apparatus configured to communicate with a terminalapparatus, the communication method comprising: transmitting controlinformation used for a scheduling of a Physical Uplink Shared Channel(PUSCH); and receiving partial precoder information that specifies atleast one preferred candidate from among a plurality of candidates ofprecoders, the partial precoder information being reported together withdata from the terminal apparatus on and the PUSCH, wherein modulationsymbols of the partial precoder information and modulation symbols ofthe data are interleaved jointly in a case that the partial precoderinformation is aperiodically reported, and modulation symbols of thepartial precoder information and modulation symbols of the data areinterleaved separately in a case that the partial precoder informationis periodically reported.